An introduction to the molecular basics of aryl hydrocarbon receptor biology.
about
Immune response and immunopathology during toxoplasmosisIntestinal inflammation and the diet: Is food friend or foe?Molecular Mechanisms of Action of BPAHypoxia-inducible aryl hydrocarbon receptor nuclear translocator (ARNT) (HIF-1β): is it a rare exception?Bisphenol A inhibits cultured mouse ovarian follicle growth partially via the aryl hydrocarbon receptor signaling pathwayExactly the same but different: promiscuity and diversity in the molecular mechanisms of action of the aryl hydrocarbon (dioxin) receptorSignaling network map of the aryl hydrocarbon receptorActivation of aryl hydrocarbon receptor (AhR) leads to reciprocal epigenetic regulation of FoxP3 and IL-17 expression and amelioration of experimental colitisKhellin and visnagin differentially modulate AHR signaling and downstream CYP1A activity in human liver cellsGender differences in transcriptional signature of developing rat testes and ovaries following embryonic exposure to 2,3,7,8-TCDDImpact of smoking on lung cancer treatment effectiveness: a review.Interaction of mammary bovine ABCG2 with AFB1 and its metabolites and regulation by PCB 126 in a MDCKII in vitro model.Genetic association of aromatic hydrocarbon receptor and its repressor gene polymorphisms with risk of rheumatoid arthritis in Han Chinese populationsEstrogen receptor α and aryl hydrocarbon receptor independent growth inhibitory effects of aminoflavone in breast cancer cells.Genome-wide survey and expression analysis of the bHLH-PAS genes in the amphioxus Branchiostoma floridae reveal both conserved and diverged expression patterns between cephalochordates and vertebratesLupinalbin A as the most potent estrogen receptor α- and aryl hydrocarbon receptor agonist in Eriosema laurentii de Wild. (Leguminosae)Intersection of AHR and Wnt signaling in development, health, and disease.Methylated phenanthrenes are more potent than phenanthrene in a bioassay of human aryl hydrocarbon receptor (AhR) signalingIn vitro re-expression of the aryl hydrocarbon receptor (Ahr) in cultured Ahr-deficient mouse antral follicles partially restores the phenotype to that of cultured wild-type mouse follicles.A genomic biomarker signature can predict skin sensitizers using a cell-based in vitro alternative to animal testsThe Ah receptor regulates growth factor expression in head and neck squamous cell carcinoma cell lines.Discovery and biological characterization of 1-(1H-indol-3-yl)-9H-pyrido[3,4-b]indole as an aryl hydrocarbon receptor activator generated by photoactivation of tryptophan by sunlightAnalysis of the AHR gene proximal promoter GGGGC-repeat polymorphism in lung, breast, and colon cancerThe aryl hydrocarbon receptor regulates an essential transcriptional element in the immunoglobulin heavy chain gene.Activation of the aryl hydrocarbon receptor by the widely used Src family kinase inhibitor 4-amino-5-(4-chlorophenyl)-7-(dimethylethyl)pyrazolo[3,4-d]pyrimidine (PP2).Aryl hydrocarbon receptor modulation of estrogen receptor α-mediated gene regulation by a multimeric chromatin complex involving the two receptors and the coregulator RIP140.Regulation of paraoxonase 1 (PON1) in PCB 126-exposed male Sprague Dawley ratsSensitivity to dioxin decreases as zebrafish matureGenetic polymorphisms in the aryl hydrocarbon receptor signaling pathway as potential risk factors of menopausal hot flashes.Ahr2-dependence of PCB126 effects on the swim bladder in relation to expression of CYP1 and cox-2 genes in developing zebrafish.The aryl hydrocarbon receptor promotes aging phenotypes across species.A constitutive active MAPK/ERK pathway due to BRAFV600E positively regulates AHR pathway in PTC.In utero exposure to dioxins and dioxin-like compounds and anogenital distance in newborns and infantsCombination effects of AHR agonists and Wnt/β-catenin modulators in zebrafish embryos: Implications for physiological and toxicological AHR functionsAryl hydrocarbon receptor controls murine mast cell homeostasis.Pelargonidin activates the AhR and induces CYP1A1 in primary human hepatocytes and human cancer cell lines HepG2 and LS174T.MicroRNA-375 regulation of thymic stromal lymphopoietin by diesel exhaust particles and ambient particulate matter in human bronchial epithelial cellsComparison of intake and systemic relative effect potencies of dioxin-like compounds in female mice after a single oral dose.Real-time recording of circadian liver gene expression in freely moving mice reveals the phase-setting behavior of hepatocyte clocks.Effects of anthocyanins on the AhR-CYP1A1 signaling pathway in human hepatocytes and human cancer cell lines.
P2860
Q24612341-A55FF793-0676-4868-89B5-29BE05103AFEQ26765223-BAC356BD-34AA-458A-83D3-9C7CA8014E13Q26770365-9C292D58-6C73-43D9-9717-1E861311113EQ27027475-15C2A8E4-21A6-4BE6-992E-36876476C71BQ28391548-33C76C5F-45E5-4D3B-B2E4-0F4B59677482Q28392826-A0F743ED-2C34-4401-B735-4E23AC4020DCQ28396094-10C46D9A-197F-4191-8976-5F977E0166C8Q28476563-F535C4E3-460A-453B-9C2D-CE7E964BA692Q28533661-5DAF2C19-F42D-45C3-A982-29D0FADE038AQ28727353-DD421714-CE1D-48B6-818A-E0E63D84DDA2Q30248968-34B29BBB-D396-408E-94D1-9CEAE2589F8EQ32182119-1AF99814-1E7A-4040-8145-09F8E9807905Q33597186-6B741246-CDE9-49E9-8C10-E1EC62C9AECAQ33680008-957172C9-5ECD-49F8-A763-4A9644719B0CQ33791439-ED1F86D6-B8B1-4478-875B-8F682DBF628FQ34067522-01990C76-E02A-4864-8968-79D6CDDA0FF4Q34486670-C5CC2289-0830-4C24-9C8D-2C49CF50F547Q34782134-8A1D5DFC-EA96-43FC-AC37-93306DAE38C3Q34809103-DE929833-82BE-4731-9986-6F86DC085E7AQ35221911-0F78C419-AD39-4C0D-8C72-519AC2A5C3A7Q35297936-2F3D34A5-F16E-4F9C-9AFB-E30B43B1632BQ35329434-AF356EDB-1881-4425-B127-A81B4CD7CBFDQ35504179-20377BA4-B690-4EC4-860D-4FC50DCCD543Q35592842-852FAE8B-D857-4C7B-8DF5-937B0ED3E211Q35680450-717D9B71-FE51-47C9-94C4-6BBF4E419A66Q35685355-59B86C51-6D98-47FC-B6FE-B56834D68AA2Q35783249-46A08A1A-90E5-4979-A238-AD0B416E6984Q35969271-544E04D4-A73A-4EB6-9C2B-771F7CD3F6FDQ36204867-F6EA4458-F24C-45D2-87E2-156CC4CDCAE5Q36485490-4D2ABD35-0A59-4951-8EC7-BE9EB88114EEQ36500567-0B16F42F-099C-435E-B1B6-ACA37B3A4593Q36544784-B71EB4CF-1FCA-4437-9A5B-FC1A9798906EQ36557551-1B1F7F2A-0134-46B5-960C-3AA06924D215Q36562928-E2E58986-8C26-48EA-96A3-0D69F2F89A7AQ36779431-29206FB5-A25B-4081-BB39-FA65C868B992Q36815972-FD1D26A8-D140-44CF-9CD2-544A497FF7F2Q36879515-AE2D0C3F-F328-4A62-BC43-8937DCAAF6D5Q36984108-69B16915-8A0E-4A75-AD05-01E3F8902C5DQ37019229-046F7318-7025-41AC-B750-4E07F8C0CB3BQ37137662-8FC43713-E478-493D-AB91-52B96638A8B2
P2860
An introduction to the molecular basics of aryl hydrocarbon receptor biology.
description
2010 nî lūn-bûn
@nan
2010年の論文
@ja
2010年学术文章
@wuu
2010年学术文章
@zh-cn
2010年学术文章
@zh-hans
2010年学术文章
@zh-my
2010年学术文章
@zh-sg
2010年學術文章
@yue
2010年學術文章
@zh
2010年學術文章
@zh-hant
name
An introduction to the molecular basics of aryl hydrocarbon receptor biology.
@en
An introduction to the molecular basics of aryl hydrocarbon receptor biology.
@nl
type
label
An introduction to the molecular basics of aryl hydrocarbon receptor biology.
@en
An introduction to the molecular basics of aryl hydrocarbon receptor biology.
@nl
prefLabel
An introduction to the molecular basics of aryl hydrocarbon receptor biology.
@en
An introduction to the molecular basics of aryl hydrocarbon receptor biology.
@nl
P2860
P356
P1433
P1476
An introduction to the molecular basics of aryl hydrocarbon receptor biology.
@en
P2093
Josef Abel
Thomas Haarmann-Stemmann
P2860
P304
P356
10.1515/BC.2010.128
P577
2010-11-01T00:00:00Z